Effect of impurity band conduction on the electrical characteristics of <i>n</i>-type CuInSe2

Essaleh, L.; Wasim, S. M.; Galibert, J.

doi:10.1063/1.1403666

Cited by 32 publications

(17 citation statements)

References 18 publications

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“…This value is very well comparable to values obtained from Hall measurements on n-type crystals and is much larger than mobilities obtained previously for polycrystalline CuInSe2 by Hall measurements. [5][6][7] In contrast, the photoconductivity spectrum for the Cu-poor CuInSe2 samples looks quite different and in fact cannot be described by the Drude formalism. [8] The real part of the photoconductivity increases with frequency while the imaginary part decreases.…”

Section: Resultsmentioning

confidence: 85%

Charge carrier mobilities and dynamics in thin film compound semiconductor materials from transient Thz absorption

Unold

Hempel

Strothkämper

et al. 2014

2014 IEEE 40th Photovoltaic Specialist Conference (PVSC)

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We use optical pump Thz probe spectroscopy to access the microscopic mobilities and fast charge carrier dynamics processes in polycrystalline chalcopyrite and kesterite thin films grown by coevaporation. In order to avoid complicating effects from the presence of Ga-gradients, ternary CuInSe 2 samples were used as a model system. Significantly different DC mobilities were found for stoichiometric and Cu-poor samples, respectively. While the stoichiometric samples exhibit Drude-like free carrier mobilities with DC mobilities up to 1200cm 2 /Vs at room temperature, the Cu poor samples show non-Drude behavior, with much lower DC mobilities, indicative of carrier localization. Kesterite materials are found to show even stronger signatures of carrier localization than the chalcopyrites.

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Section: Resultsmentioning

confidence: 85%

Charge carrier mobilities and dynamics in thin film compound semiconductor materials from transient Thz absorption

Unold

Hempel

Strothkämper

et al. 2014

2014 IEEE 40th Photovoltaic Specialist Conference (PVSC)

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“…54 and references therein). Moreover, it has been even suggested in investigations of CuInSe 2 , that the dependence of R H ( T ) is not exponential at all, whereas the resistivity-like behavior with the same value of T 0 should be addressed only to the Hall mobility 81, 82 .…”

Section: Resultsmentioning

confidence: 99%

Mechanisms of charge transfer and electronic properties of Cu2ZnGeS4 from investigations of the high-field magnetotransport

Guc

Lähderanta

Hajdeu-Chicarosh

et al. 2017

Sci Rep

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Recent development of the thin film solar cells, based on quaternary compounds, has been focused on the Ge contain compounds and their solid solutions. However, for effective utilization of Cu2ZnGeS4, deeper investigations of its transport properties are required. In the present manuscript, we investigate resistivity, ρ (T), magnetoresistance and Hall effect in p-type Cu2ZnGeS4 single crystals in pulsed magnetic fields up to 20 T. The dependence of ρ (T) in zero magnetic field is described by the Mott type of the variable-range hopping (VRH) charge transfer mechanism within a broad temperature interval of ~100–200 K. Magnetoresistance contains the positive and negative components, which are interpreted by the common reasons of doped semiconductors. On the other hand, a joint analysis of the resistivity and magnetoresistance data has yielded series of important electronic parameters and permitted specification of the Cu2ZnGeS4 conductivity mechanisms outside the temperature intervals of the Mott VRH conduction. The Hall coefficient is negative, exhibiting an exponential dependence on temperature, which is quite close to that of ρ(T). This is typical of the Hall effect in the domain of the VRH charge transfer.

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“…2 that the carrier concentration decreases with decreasing temperature and then starts to increase after going through a minimum. It is well known [21][22][23] that the carrier concentration in the conduction (valence) band increases whereas in the impurity band decreases with the increase of temperature. Furthermore, at a given temperature the total charge carrier concentration is the sum of those in the conduction (valence) and impurity bands at that temperature.…”

Section: Electrical Resistivity and Carrier Concentrationmentioning

confidence: 99%

Electrical Properties of the Ordered Defect Compound CuIn3Se5

Wasim

Rincón

Marín

2002

phys. stat. sol. (a)

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The electrical properties of n and p‐type bulk samples of CuIn3Se5 have been studied in the temperature range from 80 to 300 K. From the analysis of the temperature dependence of electron and hole concentrations in the activation regime above 110 K, the activation energy and the density of states effective mass of the charge carriers are estimated to be 36 meV and 0.13me for n‐type samples, and 28 meV and 1.07me for p‐type samples, respectively. The relatively low value of the carrier concentration in n‐CuIn3Se5 and the value in p‐CuIn3Se5 being of the same magnitude as in CuInSe2 confirms that this compound is formed due to the presence of ordered arrays of electrically inactive donor–acceptor defect pairs (2 VCu1— + InCu2+). Below 110 K, the electrical conduction in the impurity band is due to nearest neighbor hopping mechanism. The relatively low magnitude of the electron mobility and its temperature dependence in the activation regime is explained by considering, in addition to the well‐established scattering processes, a mechanism that involves the scattering of the charge carriers by ordered arrays of donor–acceptor defect pairs. At lower temperatures, the variation of the mobility is explained by taking into account the theoretical model for the thermally activated nearest neighbor hopping of the charge carriers between localized states in the impurity band.

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Effect of impurity band conduction on the electrical characteristics of n-type CuInSe2

Cited by 32 publications

References 18 publications

Charge carrier mobilities and dynamics in thin film compound semiconductor materials from transient Thz absorption

Charge carrier mobilities and dynamics in thin film compound semiconductor materials from transient Thz absorption

Mechanisms of charge transfer and electronic properties of Cu2ZnGeS4 from investigations of the high-field magnetotransport

Electrical Properties of the Ordered Defect Compound CuIn3Se5

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